PT2627825E - Thermic torpedo for preparation of reinstatement materials - Google Patents

Abstract

A thermatic torpedo for preparing and delivering reinstatement materials has an internal chamber defining at least one compartment for containing graded aggregate and a second compartment for containing a stabilising agent, an external skin for insulating the contents of said internal chamber, a cap or lid for securely containing the contents of the torpedo in which is located at least one telescopic probe which can be driven through the compartments to heat and/or mix the contents thereof and at least one aperture through which the reinstatement materials may be expelled for delivery to a work site.

Description

DESCRIPTION "THERMAL CYLINDER FOR REINTEGRATION MATERIALS"

FIELD OF THE INVENTION The invention relates to an apparatus and methods for preparing and delivering road deck reintegration materials.

BACKGROUND OF THE INVENTION The present specification, drawings and claims represent improvements and improvements of the invention disclosed in Applications Nos. 2010904627 and 2011900806. The reintegration of excavated materials from civil engineering or mining works is an activity that requires time and labor. Reintegration work is costly as a result of the association of labor costs with the cost of preparing the excavated materials for reintegration. Costs associated with the storage and maintenance of plant equipment and the excavated materials themselves are high, particularly in circumstances where a particular mixture of materials is required for proper surface re-integration.

Transportation costs are also prohibitive in many jobs or reintegration projects.

Reintegration work normally involves the removal of excavated materials and the transportation of the crushed aggregates to the reintegration site. It is a common practice to add a binder to the crushed aggregates in order to provide a stable surface upon completion of the reintegration work. There are problems associated with the on-site preparation of crushed aggregates and binders including the need to have a plant available locally to perform the binder and aggregate processing. As a rule, then, it is necessary to process and store off-site aggregate materials and to transport such materials to the site of the reintegration work. This method is expensive and requires additional resources, eg plant and fossil fuels. The aggregate and the binder should be maintained at a constant temperature to prevent solidification of the materials prior to their placement in the reintegration site. Earlier devices have failed to address this important aspect of reintegration work. It has been shown that the use of friction only by agitation or mixing of the materials is insufficient in regions where outdoor temperatures are low, in particular at negative temperatures. In such circumstances it is necessary to apply heat to the materials to ensure the viscosity of the mixture of aggregates and usefulness of the materials when dispatched.

Devices and vehicles which have been designed to permit recycling of excavated materials and delivery thereof with a suitable binder in place are known in the art. PCT / GB2009 / 050076 by Balfour Beatty describes a suction recycling arrangement which offers one of these solutions which includes the use of suction in the removal of excavated materials and apparatus for blending the materials with a binder. The proposed solution of PCT / GB2009 / 050076 presents several drawbacks in practical application, for example, the time required to process the excavated materials prior to their reintegration. The Balfour Beatty solution has an additional problem in that it requires a constant source of electric power to allow the high speed suction required for the operation of the apparatus.

Another suitable device for on-site preparation of recycled asphalt mixtures is disclosed in U.S. 4,910,540. The placement of asphalt, for example, requires the use of tar which is mixed with sand and crushed aggregate as a stabilizer to make road pavements. It is necessary to use tar in its liquid form which requires the application of constant heat to avoid solidification of the reintegration materials. Other devices that have been developed to transport reintegration materials to construction sites include hot boxes which include heating elements therein to maintain a constant temperature so that the reintegration materials housed therein do not solidify and become unusable . In use, these hot boxes require the user to constantly add aggregate materials to the hot box for blending prior to application to the reintegration site. These additional materials must be transported to the location either on a vehicle on which the hot box is mounted or on separate vehicles which may or may not retain aggregate materials of different grades. Additional transportation and fuel costs are unavoidable with the use of hot boxes as they are currently known in the art.

In traditional methods of reintegration work, there is a lot of waste and the materials become unusable once they solidify. It would therefore be desirable to provide means by which the materials could be constantly heated so as to avoid such waste.

It would also be advantageous to provide an apparatus and method for means of preparing and delivering road pavement reintegration materials which could be used in sub-zero environments with minimal waste.

Another problem associated with heating and transporting such materials is the requirement to use large quantities of petroleum-based fuels to transport materials to work sites and to maintain value and avoid waste.

It would be useful or advantageous therefore to provide an apparatus and method for providing a reintegration work site with a mixture of crushed aggregate and premixed binder which would be suitable for use on the site and which would increase the speed of delivery of the materials and the processing of the work and that would allow to avoid the waste of materials.

It would also be advantageous to provide a method for the preparation and delivery of reintegration materials to a worksite which reduces the volume of fuel required for transport, and in which fuel savings could be translated into or equated with carbon credits and so be easily accepted into new eco-friendly eco-models.

OBJECTS AND SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus and method for delivering a consistent blend of crushed aggregate to a reintegration work which is efficient and economical and overcomes at least some of the problems of the prior art.

The preferred but non-essential objects of the present invention are to provide a system for delivering road reintegration materials which is less expensive than existing methods and which overcomes the problems associated with transportation and waste.

There is also provided a method of delivering a consistent mixture of crushed aggregate to a reintegration work according to the description set forth below.

Accordingly, there is provided a thermo cylinder for preparing and delivering reintegration materials comprising: an inner chamber defining at least one compartment for containing the crushed aggregate and a second compartment for containing a binder; - an outer film for isolating the contents of said inner chamber; - a cover for securely containing the contents of the cylinder in which is located at least one telescopic probe which can be guided by the compartments for heating and / or mixing the contents thereof; - at least one aperture through which the reintegration materials can be extruded for delivery to a work site where the aggregate and binder materials are preloaded into discrete capsules which are introduced into the cylinder.

In some preferred embodiments, the cylinder may be mounted on a vehicle or a carton open for transportation.

The pre-filled capsules can be introduced into the inner chamber of the cylinder using a stem. The rod may be capable of being heated for heating the contents of the capsules.

In other preferred embodiments the cylinder may be placed within a housing.

In yet other embodiments the casing receiving the cylinder may be rotatable.

In other preferred embodiments the housing may contain a plurality of rollers.

In other embodiments the cylinder is heated using an external heat source. In some particularly preferred embodiments the contents or each compartment of each compartment within the inner chamber may be heated by exhaust gases from a vehicle on which the cylinder is mounted or from a generator to be transferred between a space defined by the outer film of the cylinder and the inner chamber. The cylinder may have an external heat source which includes the addition of exhaust gases from a motor.

In some embodiments the exhaust gases are used to guide a plurality of spoon-shaped turbine blades to allow for reduction of load on the engine components.

In other embodiments, the or each telescopic probe includes retractable ridges or blades located along its length to mix the contents of the cylinder.

In other embodiments, the rod rotates inside the inner cylinder compartment.

In yet other embodiments, the rod includes retractable razor blades located along its length to mix the contents of the cylinder.

Further embodiments include where the or each telescopic probe is introduced through the or each capsule through at least one aperture corresponding to each probe.

In other embodiments, the mixed and / or heated reintegration materials inside the cylinder are expelled into a dispensing chamber that securely engages the cylinder.

In preferred embodiments, the ejection or retention of reintegrating materials from the cylinder into the delivery chamber is possible through a retractable cover plate located between the cylinder and the delivery chamber.

In yet other embodiments, the ejection of reintegration materials from the inner chamber is possible through a hydraulic cylinder and a plunger.

Also provided is a method of delivering a consistent blend of crushed aggregate and binder to a reintegration site including the steps of: (a) preparing a mixture of premixed crushed aggregate and placing the mixture in a plurality of cylinders or tubes . b) Add binder to the aggregate. c) Maintain a constant temperature in the cylinders or tubes by placing a heating probe inside the or each cylinder or tube. d) Use a hydraulically operated plunger to eject the crushed aggregate and binder to the site through a hose or channel. e) As each cylinder or tube is emptied, the next cylinder in the housing is coupled to the plunger. f) Transport pre-filled cylinders or replacement tubes to the work site. g) Replace cylinders or empty tubes with cylinders or tubes filled periodically. h) Preload the aggregate and the binder into discrete capsules which are loaded in the or each cylinder.

There is also provided a method of delivering a consistent blend of crushed aggregate and binder to a site of the reintegration work including the steps of: i) Placing the filled cylinders or tubes within apertures formed within a casing which resembles with a cannon barrel. j) Selectively rotating the casing to facilitate mixing of materials within the cylinders or tubes.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a side view of the sections of a cylinder. Figure 2 is a view of the cap that engages the upper end of a cylinder. Figure 3 is a side view of the thermals fully extended inside a cylinder. Figure 4 shows the operation of the plunger. Figure 5 is a view of the surface of the plunger 33. Figure 6 is a view of the cylinder mounted on a vehicle. Figure 7 is an isometric view of a housing with rollers installed. Figure 8 is an exploded view of capsules ready to be loaded onto a cylinder. Figure 9 provides an isometric view of an alternate embodiment of the invention. Figures 10 to 12 provide views of the cylinder mounted on a distribution chamber. Figure 13 is an isometric view of the casing containing the cylinders. Figure 14 is a transverse isometric view of the housing. Figure 15 is a front view of the housing. Figure 16 is a side profile view of the casing with a cylinder in position. Figure 15 shows the cylinder heated using exhaust gas. Figure 16 shows detail of an alternative embodiment of mounting on a vehicle. Figure 17 is an isometric view of a capsule. Figure 18 is a cross-sectional isometric view of the inside of a capsule. Figure 19 shows the end portion of a capsule.

Figures 20-25 provide further details of the cylinder coupled to the delivery chamber.

Figures 26A, 26B, 26C and 27 provide further details of the configuration of the capsules.

Figures 28A, 28B, 29, 30 and 31 provide details of the intake and exhaust system.

Figures 32, 33 and 34 provide images of an alternative embodiment of the invention for mounting on a vehicle.

BEST MODE AND OTHER FORMS OF CARRYING OUT THE INVENTION The apparatus comprises a thermally (or heated) tube generally in the form of a cylinder 10 as shown in Fig. 1. Each cylinder has an outer film 11 and an inner film 12. A space 13 defined between each film may be a vacuum which provides thermal insulation against the outside temperatures for the contents of the cylinder. In some embodiments of the invention heated air may be pumped into the space 13 by means of a convection fan which is attached to a power source (not shown). The heated air may be exhaust gases from a vehicle on which the cylinder may be mounted for transport or may exit a generator located externally of the cylinder. See Fig. 15.

In use, the cylinder 10 is filled with crushed aggregate and a binder. In the case of most civil engineering or reintegration works using asphalt, the binder will be tar. In the case of concrete works the binder can be lime or cement with water as activator or catalyst.

An inner cylinder chamber 14 formed by the inner film 12 is filled with components of engineering materials, usually aggregate crushed, sand and binder, tar or cement and water. The cylinders may have segmented compartments 20, 21, 22 in which each component of materials is separated. In road reintegration procedures, the first compartment is filled with blue metal, the second with sand and the upper compartment with tar.

In especially preferred embodiments of the invention the crushed aggregate is charged to the cylinder or tube in preloaded cylindrical capsules (or bullets) as shown in Fig. 7 (and Fig. 10), each of which may contain a different degree of aggregate. A higher part of the filled tube contains a binder, which may be in the solid form.

In especially preferred embodiments the preloaded cylindrical capsules or bullets may be stored or deposited and collected by a user in volumes suitable for the reintegration works to be finalized. The capsules or bullets may be of various sizes and contain the volume of reintegration materials in accordance with the size of the task. Likewise, capsules / bullets may be distributed in quarter ton, half ton, one ton, two ton, five ton, or size capsules in accordance with the task to be performed. This facilitates the marketing and distribution of capsules to all parts of the reintegration industry. Builders' yards around the world can store prepackaged capsules and cylinders to be explored in the short term. Productivity begins immediately from the start of a vehicle as opposed to rehabilitation teams who waste time on asphalt loading facilities or while waiting for the aggregate to be heated. The 10 hour shifts will correspond to exactly 10 hours of active production. In the course of a major civil engineering project, cost savings and increased productivity can be quite substantial.

Those working in the field of civilian reintegration works, particularly in regions with cold climates with costs of keeping materials warm so that they are always ready to use, will be well aware of the costs associated with the delivery of reintegration materials on construction sites and the degree of waste of time and labor. On average, workforce members waste up to 2 hours of productive time while waiting to load their trucks with asphalt materials. About 2 hours more is wasted in transporting materials to and from the workplace. In essence, half the working day is non-productive time as a result of methods of delivery and processing of reintegration material and this results in excessive costs to be incurred by civilian reintegration contractors and project managers who are required to pay the costs of labor and transport as non-productive outputs.

As an example, assume that a single worker is paid at $ 25 per hour. A single worker spends 4 hours of nonproductive time every day that equals wages / wasted expenses of $ 100 per day. A team of 2 men equals wasted wages of $ 200 a day. It is established that reintegration teams working on large projects spend 7 days a week working, amounting to $ 1400 every week of non-productive labor costs (ie 7 x $ 200), or annually (ie 52 x $ 1400) $ 72,800 . In average reintegration contracts there may be 6 teams of 2 men working in a given period. Likewise, the wasted wages per day would be $ 1200, per week at $ 8400, and per year at $ 436,800. The wasted costs for a large contractor involved in many reintegration projects around the world can reach many millions or billions of dollars annually. The present invention proposes a technology and method of employing such technology that will enable civilian reintegration contractors to reduce these underlying costs significantly.

This also facilitates the creation of a new business line from traditional reintegration materials operations, namely the retailing of cylinder refills, and specially designed cylinder trailers.

Each cylinder 10 has an open proximal end 15 and a closed distal end 16. The upper or proximal end 15 of the cylinder is opened. It is equipped with a cap 30 which seals the open end 15 of the cylinder and securely contains the contents including the aggregate and binder inside the cylinder 10. The cap can be attached to the cylinder 10 by means of a hinge located at the proximal end 15 When installed, the cover provides a secure seal for the contents of the cylinder. See Fig. 2 which indicates the cap in several steps of being open or closed a., B., C. on the proximal end of the cylinder 10.

Inside the lid 30 is located at least one heated telescopic probe 31 which can be guided through each successive inner compartment 22, 21, 20, containing crushed aggregate inside the cylinder to heat the contents.

In some embodiments, the heated telescopic probe 31, or an additional telescoping probe or probes which may also be heated, may have a propeller blade 33 secured thereto for mixing the contents of the successive cylinder compartments 22, 21, 20. The contents of the cylinder are heated using the probe 31 or probes 32 which hold the aggregate and the binder at a constant temperature. In some embodiments of the invention the probe, or each probe, may be in the form of a flute or helical screw.

The probes can be powered by battery, solar energy or any other suitable power source. In particularly preferred embodiments the ambient heating of the cylinders resulting from the use of exhaust gases for heating the apparatus as indicated in Fig. 15 will effectively reduce the amount of energy required to heat the probes so that they can mix and maintain the heat of the reintegration materials within the cylinder, or each of them.

The upper compartments 22 closest to the proximal end of the cylinder 15 contain the binder, namely, tar for operations connected to the asphalt. The or each heating probe 31, 32 is activated to heat each compartment of the cylinder consecutively. As the binder, the tar, must remain in the liquid state to be mixed and bond to the crushed aggregate for use in reintegration works, it must be heated to preserve its liquid constitution. The or each probe 31, 32 may have a heating sensor attached thereto which helps the operator to maintain a constant temperature while mixing the contents of the cylinder 10. The lid 30 has a plunger 33 located on its surface closer to the interior of the cylinder 14 which is guided by a cylinder, or cylinders, hydraulic (not shown) and slidably engages within the radius of the inner cylinder film 12. When activated, the hydraulic cylinder or cylinders exerts a compressive force on the plunger 33 and forces the plunger 33 into the inner chamber 14 of the cylinder. As the plunger 33 is forced into the inner chamber of the cylinder it compresses the contents thereof. The action of the plunger 33 forces expulsion of the contents of the cylinder from the inner chamber 14 and out through an aperture 34 or a series of apertures located at the distal end 16 of the cylinder in the same way as a syringe functions to expel the contents of the it. See Fig. 4. In some preferred embodiments of the invention, the contents of the cylinder, once mixed and heated, may be expelled through a series of apertures 35 located along the inner lower surface of the cylinder. The expelled mixed reintegration materials may then be directed to, and placed over, a desired location on the site either by gravity or preferably discharged through a hose or channel member (not shown).

In yet other embodiments, the blended materials may be extruded through the aperture 34 or apertures 35 and into a second receptacle located externally of the cylinder but which may constitute a casing for the cylinder from which it may be placed on site reintegration. The openings through which the mixed materials are evacuated can be opened by guillotine valves which can be manually activated by a lever, hydraulically or by using electrical means. The action of the piston also cleans the inner surface of the cylinder while slidingly engaging the inner cylinder film so that it can be refilled with aggregate crushed and binder thereafter. The plunger has an aperture 36 located centrally and may have additional apertures 37 to allow the telescoping thermal probe or probes to be guided from within the cap 30 through the inner chamber 14 for mixing the reintegration materials into the cylinder, as shown in Fig.

In some embodiments of the invention a plurality of thermally tubes or cylinders 10 may be placed within a rotatable shell which may be mounted on a transport vehicle 75, Fig. 7. Within each cylinder is placed aggregate crushed, sand and binder which, when mixed, can be applied to road pavements and other civil works that require filling. The casing 70 may be rotated so as to facilitate the addition and removal of cylinders 10 whose contents have been expelled for refilling. The casing may be designed to receive any number of rollers 10 depending on the requirements of the user. The casing 70 is generally cylindrical in shape and has a plurality of openings for slidably receiving the filled tubes with aggregate and binder. The casing may be fed so as to provide centrifugal force on the contents of the rollers and thus assist in mixing the crushed aggregate and the binder inside each roll.

While a cylinder 10 is emptied the operator may couple another one of the cylinders until the materials within all of the cylinders are exhausted. The empty cylinders may be withdrawn and replaced by cylinders which have been preloaded with aggregate and binder ready to mix even while continuing in place. The casing 70 may be raised and lowered to withdraw the empty cylinders and introduce the preloaded replacement cylinders. The transport of the bulk cylinders to the site of the reintegration work is possible, which entails considerable savings compared to the time required to load and unload trucks with aggregate crushed.

Preferably the cylinders and plunger are made of steel although any suitably strong and strong materials such as stainless steel, galvanized steel, aluminum or even strong molded plastic may be used. In some embodiments of the invention, the cylinder may be fabricated from a highly durable resin, plastic or similar material which may be impregnated or coated with a catalyst or binder that reacts with the contents of the cylinder, particularly when heat is applied thereto. Such a resin impregnated cylinder or catalyst coating can significantly reduce the overall weight of the machinery needed to complete the reintegration works and the transportation cost of the reintegration materials to a site of the work. The use of such materials can significantly reduce the overall costs of reintegration works, improve the efficiency with which such works are conducted and improve the ease with which such works are carried out.

As indicated in Fig. 6, the cylinder may be mounted on a vehicle or carton open for towing and raised and lowered using one or a plurality of hydraulic cylinders 51 to facilitate ejection of the reintegration materials from the interior of the cylinder and for easy placement of the reintegration materials at a site of work and expulsion through a hose or channel 53. Depending on the size of the cylinder or cylinders placed on the transport vehicle the vehicle may have tires or may require tracks of caterpillars. Other vehicle mounting configurations are possible with one of these alternate configurations indicated in Fig.

In some embodiments of the invention, the crushed aggregate, sand and binder may be preloaded into separate containers or caps 81,82,83. Each capsule may alternatively contain a single component of reintegrating materials for mixing within the cylinder 10. The caps 81, 82, 83 have a central aperture through which a rod can be threaded which allows the capsules to be introduced into the, or a cylinder in anticipation of transport to a site of work or mixing. The rod 80 may have retractable barbs 84 which open to secure the caps 81,82,83 to the rod so that they can be moved into position within the cylinder and that can be collected to withdraw the rod 80 once the capsules are in place.

In some embodiments the rod may serve as the heat probe and / or the mixing probe and may be attached to the cap 30.

In yet other embodiments of the invention the caps 81,82,83 may be charged directly into the inner chamber of the cylinder 14 and the rod 80 guided through successive capsules so as to allow mixing of the contents and the action of the piston 33 to expel the reintegration materials blended from the cylinder 10.

Cylinders in Gatling Drum casings (see Fig. 7 and Fig. 10), or independent cylinders, may keep both capsules or the aggregate housed therein preheated, by use for example of hot air stream or heating of resistance power. Those skilled in the art will appreciate the possibility of using other heating methods and which may be incorporated into the apparatus and method described herein without changing the scope of the invention.

This heating takes place prior to the actual thermal mixing process wherein the aggregate and binders inside the capsules are activated from the application site at a reintegration site, thereby dramatically reducing the amount of heat source required and the energy required to heat the reintegration materials . Effectively driving the cylinders on a wagon from A to B will produce heated air from the exhaust system of the engine which when applied will produce 75% of the required heat. Thus, only 25% of the required heat source is essential for the final blending process, since both the aggregates and the capsules containing the binder are preheated in transit. This can also be applied to independent cylinders stacked in transport.

Suitable heat sources that can be employed to heat the cylinders include: 1. Exhaust thrust pressure to rotate and heat the blades of the copper turbine, and transfer heat to the air in the clean air tank. 2. Heat the stop plates to heat the resistance in pre-packed bales. 3. Hot exhaust pulse pressure to further rotate the alternator armature to serve as an electrical source. 4. Hydraulic pressure (propulsion running outside the turbine rod). 5. Thermally-accurate drum attachment (Quick-fit) from independent machines, ie both vehicles and track machines. 6. Generators of 240-110V, ie pickups or 1-ton pick-up (PTO) on 3-7-12 Ton vehicles. Operation during towing. Tailored trailers transport Thermo Cylinders to the site. 7. Manual cylinders in small bogies with wheels. 8. Solar panel heat source can be used in suitable climates such as equatorial or desert areas. 9. Each capsule either contains aggregate or pre-fabricated solid substance with aligned strength elements to match each capsule. 10. Universal hydraulic heating disc with quick-fit accessory. The heating disc may be located and secured to the rear of the aligned vehicles or track vehicle arms. Figure 9 provides an isometric view of an alternate embodiment of the invention. The cylinder 10 is releasably mounted on a second cylinder-shaped distribution chamber into which pre-fabricated capsules 84 are loaded, each containing reinstating materials for mixing, batting and delivery to a work site, which may is seen in cross-section in Figure 10. The loading port 96 allows access to the inner compartment of the cylinder 10 to introduce the caps 84. The caps 84 are threaded onto the scored rod 85 which passes through the center of the inner compartment of the cylinder forming a chamber heating and mixing. The splined shank 85 is heated by the heat source 97 which is mounted on the opposing end of the cylinder 10 to the loading port 96 and is rotatable so as to permit mixing of the reintegration materials housed within the caps 84 by retractable barbs 101 located along the length of the rod 85 (not shown). The heat source 97 is fed by a coated motor 98 which is mounted on the heat source 97 at the farthest end of the cylinder 10. The contents of the capsules are mixed in the upper heating and mixing chamber and expelled through the apertures 35 located in the the lower inner surface of the chamber. The apertures may be opened or closed by the operator by a retractable plate cover (not shown) so as to permit the discharge of mixed materials from the upper chamber into the delivery chamber 90. The delivery chamber 90 has a hydraulic power station 99 mounted thereon at the same end while the heat source 97 and the motor 98 are situated on the cylinder 10. The hydraulic power station 99 incorporates a telescopic cylinder 91 which guides a piston 33 to discharge heated reintegration materials and mixed through the mackerel point 38 for the desired site of work. Figure 11 shows the front end view of the cylinder and delivery chambers and indicates the position of the retractable barbs 101 within the cylinder when in use. In alternative embodiments, the barbs may be located within each capsule 84 and are coupled when the capsules are charged to the cylinder 10 along the scored rod 85 so as to allow rotation of the barbs within each mixing capsule and heating the reintegration materials housed therein. Figure 13 is an isometric view of the above-described housing 70 housing a plurality of cylinders 10 therein. Loading ports 96 of each cylinder housed within the housing 70 are indicated in the closed position. The casing 70 may be rotated so as to allow alignment of each cylinder 10 housed therein to be releasably mounted or coupled to the delivery chamber 90 which may be in a fixed position. Alternatively the dispensing chamber rotates around the casing 70 so as to allow the discharge of heated and mixed reintegration materials into the work site by the user. In certain embodiments, the heat source 97 and the motor 98 may be located within the housing or on its outer surface corresponding to the or each cylinder. In alternative embodiments, for use in hot climates that do not require high heating to achieve a feasible temperature for reintegrating materials, a single heat source 97 and motor 98 may be securely mounted on the delivery chamber 90 in in which case the casing 70 rotates to allow coupling of the fixed heat source to each cylinder 10 while the casing 70 rotates. Figure 14 is a cross-sectional view of the housing 70 in which the lower cylinder 10A is in position coupled to the delivery chamber 90. In the figure, the heat source 97 for each cylinder is located within the housing 70 so as to allow heating of the materials within each capsule 84 before arriving at the site of the work. This allows to reduce the time to the optimum temperature for mixing and delivery of on-site reintegration materials. Figure 15 is a front view showing the coupling of the cylinder 10 to the delivery chamber 90 even though still retained within the housing 70. Figure 16 indicates the plunger 33 guided by the hydraulic cylinder 91 moving toward the outlet point 38 which permits the discharge of mixed materials from the delivery chamber 90. Figure 17 shows an isometric view of a capsule 84. The capsule 84 is made of durable, durable resin that may deteriorate or break through the application of heat and / or a chemical catalyst so as to aid or facilitate a thermal reaction which may be shortened for the time required to heat the reintegration materials contained within the capsule 84 to a temperature at which they can be used on site. As indicated in Figures 18 and 19 the cap 84 incorporates a series of apertures 103 located at each one of its ends corresponding to channels 104 to allow a plurality of heating elements to be guided through the holes and the body of the cap 85 to facilitate the heating of the materials contained therein. The capsule 84 has a centrally slotted aperture 105 which receives the fluted rod 85 from the cylinder when loaded into the cylinder 10. Figure 20 provides detail of the resin caps 84 which are each loaded with components of reintegration materials tar 10, sand 108, ballast 109 and crushed aggregate 110. The caps 84 are shown in the loading position in the heating and internal mixing chamber 14 located inside the cylinder 10 in Figure 21.

Once loaded, the contents of the capsules 84 may be heated and mixed by the fluted rod. Figure 15 provides a view of the preferred inlet and exhaust system that can be mounted to one end of the cylinder 85 extending through the cylinder. In some embodiments, the mixing blades 112 extend from the splined shank 85 when in use to mix reintegration materials. In alternative embodiments, the blending blades 112 or 101 may be located within each capsule and engage the grooved rod 85 which rotates to blend the materials. Alternatively, the mixing blades 112 may be moved along the scored rod 85 on a telescopic cylinder as shown in Figure 22. Figure 24 shows the heated and mixed reintegrating material 111 in position within the dispensing chamber 90 ready to is discharged at the site of the work through the mackerel point 38 by means of the plunger 33 guided by the hydraulic cylinder 91 as shown in Figure 25.

Figures 26 and 27 are further views of the caps 84. The apertures 103 may receive resistance 112 or thermal probes 32 to allow heating and mixing of the contents of the caps 84. Figure 28A and 28B respectively show the internal workings and the external view of the source of heat 97 which allows the rotation of the fluted rod 85 and the heating of the contents of the cylinder and the hydraulic power station 98 which guides the distribution cylinder 91 through the delivery chamber 90 to expel the mixed reintegrating materials 111. As previously indicated, the heat source 97 has a motor 98 mounted thereon. The motor can be releasably mounted on the heat source 97 or may be integral therewith depending on the requirements of the users.

In case the engine 98 is a carbon fuel engine, the heat source may be supplied by exhaust gases which are supplied to the high temperature heat source. The heat source 97 has an inner inner tube 200 and a pair of exhaust gas chambers 202 in which are located a series of spoon-shaped turbine blades 201 which rotate about a central shaft 208 movement from which it is guided by the motor 98. Intake and exhaust systems 203, 204 add momentum to the rotating turbine blades and may assist in the heating and mixing action of the fluted rod 85 within the cylinder mixing chamber. The exhaust gases are withdrawn or expelled through the outlet 205 and may be treated prior to being exhausted to the environment by means of a catalytic converter of the exhaust filter (not shown) as indicated in Figure 30.

In other embodiments, the heat source 97 only heats the fluted rod 85 and does not aid in the blending function. The spoon turbine blades are preferably made of copper or some other material that conducts heat and is resistant to corrosion by exhaust fumes. The heat source 97 may be connected to the hydraulic power station 99 by means of a pair of toothed wheels which are securely mounted on each of the central rods 208 of the heat source 97 and a central rod 209 of the hydraulic power station 99 and a belt which allows the driving of each rod 202,209 and the operation of the turbines 201 and the telescopic hydraulic cylinder 91. The rotation of the turbines 201 which rotate in reaction to the exhaust has and the air intake acts to reduce the pressure and wear of the engine components 98. Furthermore, the use of hot exhaust gases effectively reduces the energy consumption required to heat the reintegration materials into the cylinder. Figure 32 shows an alternative embodiment of the present invention that is adapted for mounting on a vehicle or an open box trailer. Thermally cylinders are loaded horizontally into the housing 70 which is pivotally mounted on the surface 215 of an open carton vehicle or trailer. The casing 70 and the surface 215 are attached through a support arm 216. The casing 70 is raised or lowered as necessary to load the cylinders 10 by means of a hydraulic cylinder (not shown). Other alternative mechanisms for raising or lowering are possible, for example, electrical media. A tar heating chamber 210 is mounted within a heated mixing bowl 217. The tar heating chamber 210 swings from the heated mixing bowl 217 for maintenance and cleaning. The heated mixing bowl 217 contains turbine blades for mixing heated and mixed reintegration materials and maintaining those materials at a constant temperature suitable for on-site distribution. The casing 70 has an exhaust pipe or exhaust hose 218 inserted therein which feeds exhaust gases from a motor (not shown) to and around an internal circularly displaced chamber bore that allows exhaust gases to warm the contents of the cylinders when they are inside the casing. The exhaust gases do not come into contact with the contents of the cylinders since the cylinders are insulated from the gases inside the casing.

In alternative embodiments of the invention, the heat source 97 and the motor 98 may be located within the vehicle or under the surface 215 of the trailer in accordance with the user's design requirements.

Some of the advantages of the present invention over the prior art solutions are: 1. cutting the costs associated with the storage and transportation of reintegration materials; 2. cut off the waste by allowing heating at the site of the binder; 3. increase efficiency; 4. reduce the amount of fuel needed for transport and thus reduce carbon emissions; 5. to reduce the carbon emissions that can be sold or saved as credit; 6. have multiple applications at the level of industry, civil engineering and agriculture.

In parallel with the above advantages, it can be seen that employing an operating system of a reintegration material plant using thermally cylinders and prefabricated caps has other advantages related to land use. Usually asphalt plants require a large amount of space, are responsible for high levels of air pollution and aesthetics and constitute an inefficient use of land in open spaces particularly in countries where land for communal, retail, commercial or other uses is limited . The use of the apparatus and method described herein will enable asphalt plant owners to reduce the size of property necessary to efficiently operate reintegration operations that will liberate that land for housing developments or the like.

Alternative embodiments of the invention described herein are possible according to the requirements of the users.

Those of skill in the art will appreciate that there are a variety of applications for which the present device and method are well-suited.

Those of skill in the art will appreciate that the apparatus and method described herein may be adapted to the requirements of the users without departing from the scope of the invention.

Lisbon, December 26, 2014

Claims (14)

A thermocontractor 10 for preparing and delivering reintegrating materials comprising: an inner chamber 14 defining at least one housing 20, 21, 22 for containing crushed aggregate and a second compartment 20, 21, 22 for containing a binder; an outer film 11 for isolating the contents of said inner chamber; a lid 30 to securely contain the contents of the cylinder in which is located the at least one telescopic probe 31, 32 which can be guided through the compartments to heat and / or mix the contents thereof; at least one aperture 34, 38 through which the reintegration materials can be extruded for delivery to a site; wherein the aggregate and binder materials are preloaded into discrete 81-84 capsules which are introduced into the cylinder. The cylinder of Claim 1 mounted on an open carton vehicle or trailer 50. The cylinder of Claim 1, wherein the capsules are introduced into the inner chamber of the cylinder using a rod 80, the rod being optionally heated to heat the contents of the capsules, and optionally being rotatable within the inner cylinder compartment. The cylinder of Claim 1, wherein the cylinder is disposed within a housing 70, the housing containing one or a plurality of cylinders. The cylinder of Claim 4, wherein the casing 70 receiving the cylinder is rotatable. The cylinder of Claim 1, wherein the cylinder is heated using an external heat source 97. The cylinder of Claim 6, wherein the external heat source includes adding exhaust gases from a motor 98. The cylinder of claim 7, wherein the exhaust gases are used to guide a plurality of scoop-shaped turbine blades 201 to allow for reduction of load on the engine components. The cylinder of claim 1, wherein the or each telescopic probe includes barbs 101 or retractable blades 112 located along its length to mix the contents of the cylinder. The rod of Claim 4, wherein the rod 85 includes barbs 101 or blades 112 retractable along its length to mix the contents of the barrel. The cylinder of Claim 2, wherein the or each telescopic probe is introduced through the or each capsule through at least one aperture 103 corresponding to each or each probe. The cylinder of Claim 1, wherein the mixed and / or heated reintegration materials are extruded into a delivery chamber 90 which is securely coupled to the cylinder. The cylinder of claim 12, wherein the ejection or retention of reintegration materials from the cylinder into the delivery chamber 90 is allowed by a retractable cover plate. The cylinder of Claim 1, wherein the expulsion of the reintegrating materials from the inner chamber is permitted by a hydraulic cylinder 91 and a piston 33. A method of providing a mixture of crushed aggregate and binder to a reintegration site including the steps of: (a) preparing a mixture of premixed crushed aggregate and placing it in a plurality of cylinders or tubes 10, placed in the inside a housing (70). b) Add binder to the aggregate; c) Maintaining a constant temperature in the cylinders or tubes by placing a heating probe 31, 32 inside the or each cylinder or tube. d) Using a hydraulic power plunger 33 to expel the crushed aggregate and binder to the site through an aperture 34, 38. e) As each cylinder or tube is emptied, the next cylinder in the housing 70 is coupled to (f) Transport pre-filled cylinders or replacement tubes to the work site. g) Replace cylinders or empty tubes with cylinders or tubes filled periodically. h) In which the crushed aggregate and the binder are preloaded into discrete 81-84 capsules which are loaded into or into each cylinder and optionally further comprises: i) Placing the filled cylinders or tubes within apertures formed within a a casing that resembles a cannon barrel. Lisbon, December 26, 2014